JPH0464334A - Blood pressure measuring apparatus - Google Patents

Abstract

PURPOSE:To obtain a correct blood pressure value regardless of a pressure blood measuring part by including an arithmetic means which detects a hydrostatic pressure difference between the blood pressure measuring part and a heart part to add the hydrostatic pressure difference detected to or subtract it from a measured blood pressure value at the blood pressure measuring part based on a positional relation between the blood pressure measuring part and the heart part. CONSTITUTION:A data processing section 9 performs a specified computation based on data supplied to calculate a maximum blood pressure, an average blood pressure, a minimum blood pressure, number of pulses and the like. In this case, the data processing section 9 subtracts a hydrostatic pressure difference between a hand finger base and a heart part obtained with a pressure sensor 19 from a blood pressure value at the hand finger base as calculated from a cuff and bag pressure based on an output of a phototransistor 18 to correct measuring errors due to a height difference between the hand finger base and the heart part. Here, as the hand finger base is lower than the heart part, a higher value is obtained than a blood pressure value obtained by measurement thereby obtaining a blood pressure value at the heart part with the subtraction of the hydrostatic water pressure difference from the value.

Description

DETAILED DESCRIPTION OF THE INVENTION "Field of Industrial Application" The present invention relates to a blood pressure measuring device, and particularly to a blood pressure measuring device that can obtain accurate blood pressure values.

``Prior Art'' Originally, blood pressure refers to blood pressure at the heart (aorta), but since it is physically difficult to directly measure blood pressure at these locations, conventional techniques generally refer to blood pressure at the head or upper arm. Blood pressure is measured in various parts of the body, including the abdomen, thighs, and fingers.

1 Invention or Problem to be Solved" By the way, there is a big difference in position between the head and the heart,
Approximately 20 to 80 mmJ-1 for areas such as thighs and fingers
Conventionally, blood pressure is measured at the upper arm, which is located at the same position as the heart, when fishing on a boat. However, the blood pressure value obtained at this site differs depending on the body position (standing position, lying position, supine position, etc.), apart from the physiological difference and transbody mechanical difference with respect to the heart.

This invention was made in view of these circumstances,
It is an object of the present invention to provide a blood pressure measuring device that can obtain accurate blood pressure values regardless of the blood pressure measurement site.

"Means for Solving the Problems" The present invention is based on a hydrostatic pressure difference detection means for detecting a hydrostatic pressure difference between a blood pressure measurement site and the heart, and a positional relationship between the blood pressure measurement site and the heart. It is characterized by comprising a calculation means for adding or subtracting the hydrostatic pressure difference detected by the hydrostatic pressure difference detection means from the blood pressure measurement value at the blood pressure measurement site.

According to the configuration described in ``Effect'', the hydrostatic pressure difference detection means detects the hydrostatic pressure difference between the heart region and the blood pressure measurement site, and this detection result is added to the blood pressure measurement value at the measurement site by the calculation means. or subtracted.

Therefore, even if blood pressure is measured at a site other than the heart, the blood pressure value at the heart can be obtained.

"Embodiments" Hereinafter, embodiments of the present invention will be described with reference to the drawings.

FIG. 1 is a perspective view showing the appearance of a blood pressure measuring device 1 according to an embodiment of the present invention. As shown in this figure, the blood pressure measuring device 1 is composed of a device body 2, a cuff part 3, and a chest unit 4, and uses a volume vibration method using photoplethysmography to measure blood pressure and pulse rate. The system calculates the systolic blood pressure, mean blood pressure, diastolic blood pressure, and pulse rate from the measurement results, and displays the six calculation results numerically on a display and prints them on a printer.

Here, details of the blood pressure measuring device 1 will be explained with reference to FIG. 2.

The device main body 2 controls a cuff pressure section 6 for sending air to the cuff section 3 via a cuff pressure line 5 and other parts of the device, reads various signals supplied from the cuff section 3, and records digital data. an input unit 8 for inputting various data (weight, height, gender, etc.), and a control unit 7 for converting and outputting data such as systolic blood pressure, average blood pressure, and minimum blood pressure based on the various data output from the control unit 7. A data processing unit 9 that calculates blood pressure, pulse rate, etc., a printer 10 that prints out various information output from the data processing unit 9, and a data monitor 1 that displays various data output from the control unit 7 and the data processing unit 9.
1, and a power supply unit 12 that supplies power to each part of the apparatus. The control unit 7 includes a CPU (central processing unit), a ROM (read only memory), and a RAM (not shown).
(Random Access Memory), an interface, etc., and a program for controlling the CPU is written in the ROM.

As shown in the figure, the cuff part 3 includes a substantially cylindrical fixing part 15 for fixing the base of the finger, a compression cuff 16 attached to the inside of the fixing part 15, and an LED attached to the upper inner side of the fixing part 15. (Light emitting element) 17 and this LEDl7
a phototransistor (light-receiving element) 18 attached to the inner lower part of the fixed part 15 opposite to the pressure sensor 19;
It is configured to include an amplifier 20 that separately amplifies the output of the phototransistor 18 and the output of the pressure sensor 19. In this case, the amplification factor of the amplifier 20 can be arbitrarily varied, so that the pressure sensor 19
The sensitivity can be adjusted.

The LED + 7 and the phototransistor 18 are used to detect blood pressure and pulse rate based on the volume vibration method described above. In this case, the lighting of the LEDs 1 and 7 is controlled by the control unit 7 of the device main body 2, and the output of the phototransistor 18 is controlled by the control unit 7. Moreover, the pressure sensor 19 detects the pressure applied from the chest unit 4, which will be described later.

As shown in FIG. 3, the chest unit 4 has a lower part 4a.
It has a tapered cylindrical shape, and the upper part 4b is removable with a screw.

In this case, the upper part 4b is removable in order to inject liquid (water, oil, etc.) into the chest unit 4. The lower end of the chest unit 4 is open, and the upper end is closed except for the air hole 4c as shown. In the air hole 4c,
A valve (not shown) is installed to prevent liquid leakage. One end of a tube 21 is connected to the lower end of the chest unit 4, and the other end of the tube 21 is connected to a detection end of a pressure saw sensor 19, as shown in FIG. Furthermore, a locking member 4d is attached to the upper part 4b of the chest unit 4 for locking the unit 4 to a chest pocket of clothing or the like. In this case, the locking member 4d is rotatable in the vertical direction with respect to the chest unit body, so that the unit body can always be oriented vertically. By locking this chest unit 4 to a portion such as a chest pocket where the heart is located, a pressure corresponding to the height from the heart to the base of the finger is applied to the detection surface of the pressure sensor 19.

In the blood pressure measuring device configured as described above, after the chest unit 4 is locked in the chest pocket, the upper part 4b of the unit 4 is removed, and liquid is injected until the liquid level reaches the position of the heart. Next, the sensitivity of the pressure sensor 19 is set to a sensitivity corresponding to the ratio of the specific gravity of the liquid to the specific gravity of blood. Next, insert your fingers into the cuff portion 3. Then, a measurement start switch (not shown) is turned on. As a result, air is supplied to the compression cuff 16, and the base of the finger is compressed. At this time, the output of the phototransistor 18 is amplified by the amplifier 20, and the output of the pressure sensor 19 is amplified by the amplifier 20. The amplified outputs are then supplied to the control section 7, converted into digital data, and then supplied to the data processing section 9. The data processing unit 9 performs predetermined calculations based on the supplied data to calculate systolic blood pressure, mean blood pressure, diastolic blood pressure, pulse rate, etc. In this case, the data processing unit 9 uses the pressure sensor 19 to add the blood pressure value at the base of the finger calculated from the cuff pressure based on the output of the foot transistor 18.
The difference in hydrostatic pressure between the base of the finger and the heart obtained by this method is subtracted to correct the measurement error due to the height difference between the base of the finger and the heart. In this case, since the base of the finger is located at a lower position than the heart, a value higher than the blood pressure value obtained by measurement can be obtained. By subtracting the hydrostatic pressure difference from this value, the blood pressure value at the heart can be obtained.

In the above embodiments, the measurement site was the base of the finger, but if cuff sections with shapes corresponding to various sites are prepared, blood pressure values corresponding to each site can be determined. In this case, if a site lower than the heart is selected as the measurement site, like the base of the finger described above, the hydrostatic pressure difference between that site and the heart is added to the blood pressure value obtained by measurement. vice versa,
If a region higher than the heart 11 is selected as the measurement region, the hydrostatic pressure difference between that region and the heart is subtracted from the blood pressure value obtained by measurement.

In addition, in the above embodiment, the light emitting element is LED
It is possible to use the transistor 18 as the light receiving element 18, or other lamps as the light emitting element, and as the light receiving element, a photodiode, C
D5 (cadmium cell) etc. can be used.

In addition, as another embodiment of the above embodiment, if a liquid with a specific gravity equivalent to that of blood is used as the medium for detecting the hydrostatic pressure difference, and a differential pressure type pressure sensor is used as the pressure sensor, the same as in the above embodiment can be obtained. Blood pressure can be measured while always correcting the hydrostatic pressure difference without performing addition/subtraction processing.

"Effects of the Invention" As explained above, the blood pressure measuring device according to the present invention detects the hydrostatic pressure difference between the blood pressure measurement site and the heart, and uses this hydrostatic pressure difference between the blood pressure measurement site and the heart. Since the blood pressure value is added to or subtracted from the blood pressure value obtained from the measurement site based on the relationship, measurement errors due to differences in height of the blood pressure measurement site from the heart can be eliminated, and accurate blood pressure values can be obtained.

[Brief explanation of the drawing]

FIG. 1 is a perspective view showing the external appearance of a blood pressure measuring device according to an embodiment of the present invention, FIG. 2 is a block diagram showing the schematic configuration of the device, and FIG. 3 is an external view of a chest unit constituting the device. FIG. 2... Device body, 3. 4... Chest unit, I9... Pressure sensor, 21- tube. - Cuff part, 7... Control part, 20... Amplification part,

Claims (1)

[Scope of Claims] Hydrostatic pressure difference detection means for detecting a hydrostatic pressure difference between a blood pressure measurement site and the heart; and a hydrostatic pressure difference detection means for detecting a hydrostatic pressure difference between the blood pressure measurement site and the heart. A blood pressure measuring device comprising: arithmetic means for adding or subtracting a detected hydrostatic pressure difference to or from a blood pressure measurement value at the blood pressure measurement site.